Ghayda M Mirzaa1,2, Catarina D Campbell3, Nadia Solovieff3, Carleton Goold3, Laura A Jansen4, Suchithra Menon3, Andrew E Timms5, Valerio Conti6, Jonathan D Biag3, Carissa Adams2, Evan August Boyle7, Sarah Collins2, Gisele Ishak8, Sandra Poliachik8, Katta M Girisha9, Kit San Yeung10, Brian Hon Yin Chung10, Elisa Rahikkala11, Sonya A Gunter4, Sharon S McDaniel12, Colleen Forsyth Macmurdo13, Jonathan A Bernstein13, Beth Martin14, Rebecca Leary3, Scott Mahan3, Shanming Liu3, Molly Weaver15, Michael Doerschner15, Shalini Jhangiani16,17, Donna M Muzny16,17, Eric Boerwinkle17,18, Richard A Gibbs16,17, James R Lupski16,17,19,20, Jay Shendure14, Russell P Saneto21,22, Edward J Novotny2,21, Christopher J Wilson23, William R Sellers3, Michael Morrissey3, Robert F Hevner2,24, Jeffrey G Ojemann24, Renzo Guerrini6,25, Leon O Murphy3, Wendy Winckler3, William B Dobyns1,2. 1. Division of Genetic Medicine, Department of Pediatrics, University of Washington, Seattle, Washington, USA. 2. Center for Integrative Brain Research, Seattle Children's Research Institute, Seattle, Washington, USA. 3. Novartis Institutes for BioMedical Research, Inc., Cambridge, MA. 4. Department of Neurology, University of Virginia, Charlottesville, VA, USA. 5. Center for Developmental Biology and Regenerative Medicine, Seattle Children's Research Institute, Seattle, Washington, USA. 6. Paediatric Neurology, Neurogenetics and Neurobiology Unit and Laboratories, A. Meyer Children's Hospital, and Department of Neuroscience, Pharmacology and Child Health, University of Florence, Florence, Italy. 7. Department of Genetics, Stanford University School of Medicine, Stanford, California, USA. 8. Department of Radiology, Seattle Children's Hospital, Seattle, Washington, USA. 9. Department of Medical Genetics, Kasturba Medical College, Manipal University, Manipal, Karnataka, India. 10. Department of Pediatrics and Adolescent Medicine, Li Ka Shing Faculty of Medicine, The University of Hong Kong, Hong Kong, China. 11. PEDEGO Research Group and Medical Research Center Oulu, University of Oulu and Department of Clinical Genetics, Oulu University Hospital, Finland. 12. Pediatric Neurology and Epilepsy, Kaiser Permanente San Francisco Medical Center, San Francisco, California, USA. 13. Division of Medical Genetics, Department of Pediatrics, Stanford University, Stanford, California, USA. 14. Department of Genome Sciences, University of Washington, Seattle, Washington, USA. 15. Department of Pathology, University of Washington, Seattle, Washington, USA. 16. Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, USA. 17. Human Genome Sequencing Center, Baylor College of Medicine, Houston, Texas, USA. 18. Human Genetics Center, University of Texas Health Science Center at Houston, Houston, Texas, USA. 19. Department of Pediatrics, Baylor College of Medicine, Houston, Texas, USA. 20. Texas Children's Hospital, Houston, Texas, USA. 21. Division of Pediatric Neurology, University of Washington, Seattle, Washington, USA. 22. Center for Developmental Therapeutics, Seattle Children's Research Institute, Seattle Washington, USA. 23. Editas Medicine, Cambridge, Massachusetts, USA. 24. Department of Neurosurgery, University of Washington, Seattle, Washington, USA. 25. IRCCS Stella Maris Foundation, Pisa, Italy.
Abstract
IMPORTANCE: Focal cortical dysplasia (FCD), hemimegalencephaly, and megalencephaly constitute a spectrum of malformations of cortical development with shared neuropathologic features. These disorders are associated with significant childhood morbidity and mortality. OBJECTIVE: To identify the underlying molecular cause of FCD, hemimegalencephaly, and diffuse megalencephaly. DESIGN, SETTING, AND PARTICIPANTS: Patients with FCD, hemimegalencephaly, or megalencephaly (mean age, 11.7 years; range, 2-32 years) were recruited from Pediatric Hospital A. Meyer, the University of Hong Kong, and Seattle Children's Research Institute from June 2012 to June 2014. Whole-exome sequencing (WES) was performed on 8 children with FCD or hemimegalencephaly using standard-depth (50-60X) sequencing in peripheral samples (blood, saliva, or skin) from the affected child and their parents and deep (150-180X) sequencing in affected brain tissue. Targeted sequencing and WES were used to screen 93 children with molecularly unexplained diffuse or focal brain overgrowth. Histopathologic and functional assays of phosphatidylinositol 3-kinase-AKT (serine/threonine kinase)-mammalian target of rapamycin (mTOR) pathway activity in resected brain tissue and cultured neurons were performed to validate mutations. MAIN OUTCOMES AND MEASURES: Whole-exome sequencing and targeted sequencing identified variants associated with this spectrum of developmental brain disorders. RESULTS: Low-level mosaic mutations of MTOR were identified in brain tissue in 4 children with FCD type 2a with alternative allele fractions ranging from 0.012 to 0.086. Intermediate-level mosaic mutation of MTOR (p.Thr1977Ile) was also identified in 3 unrelated children with diffuse megalencephaly and pigmentary mosaicism in skin. Finally, a constitutional de novo mutation of MTOR (p.Glu1799Lys) was identified in 3 unrelated children with diffuse megalencephaly and intellectual disability. Molecular and functional analysis in 2 children with FCD2a from whom multiple affected brain tissue samples were available revealed a mutation gradient with an epicenter in the most epileptogenic area. When expressed in cultured neurons, all MTOR mutations identified here drive constitutive activation of mTOR complex 1 and enlarged neuronal size. CONCLUSIONS AND RELEVANCE: In this study, mutations of MTOR were associated with a spectrum of brain overgrowth phenotypes extending from FCD type 2a to diffuse megalencephaly, distinguished by different mutations and levels of mosaicism. These mutations may be sufficient to cause cellular hypertrophy in cultured neurons and may provide a demonstration of the pattern of mosaicism in brain and substantiate the link between mosaic mutations of MTOR and pigmentary mosaicism in skin.
IMPORTANCE: Focal cortical dysplasia (FCD), hemimegalencephaly, and megalencephaly constitute a spectrum of malformations of cortical development with shared neuropathologic features. These disorders are associated with significant childhood morbidity and mortality. OBJECTIVE: To identify the underlying molecular cause of FCD, hemimegalencephaly, and diffuse megalencephaly. DESIGN, SETTING, AND PARTICIPANTS: Patients with FCD, hemimegalencephaly, or megalencephaly (mean age, 11.7 years; range, 2-32 years) were recruited from Pediatric Hospital A. Meyer, the University of Hong Kong, and Seattle Children's Research Institute from June 2012 to June 2014. Whole-exome sequencing (WES) was performed on 8 children with FCD or hemimegalencephaly using standard-depth (50-60X) sequencing in peripheral samples (blood, saliva, or skin) from the affected child and their parents and deep (150-180X) sequencing in affected brain tissue. Targeted sequencing and WES were used to screen 93 children with molecularly unexplained diffuse or focal brain overgrowth. Histopathologic and functional assays of phosphatidylinositol 3-kinase-AKT (serine/threonine kinase)-mammalian target of rapamycin (mTOR) pathway activity in resected brain tissue and cultured neurons were performed to validate mutations. MAIN OUTCOMES AND MEASURES: Whole-exome sequencing and targeted sequencing identified variants associated with this spectrum of developmental brain disorders. RESULTS: Low-level mosaic mutations of MTOR were identified in brain tissue in 4 children with FCD type 2a with alternative allele fractions ranging from 0.012 to 0.086. Intermediate-level mosaic mutation of MTOR (p.Thr1977Ile) was also identified in 3 unrelated children with diffuse megalencephaly and pigmentary mosaicism in skin. Finally, a constitutional de novo mutation of MTOR (p.Glu1799Lys) was identified in 3 unrelated children with diffuse megalencephaly and intellectual disability. Molecular and functional analysis in 2 children with FCD2a from whom multiple affected brain tissue samples were available revealed a mutation gradient with an epicenter in the most epileptogenic area. When expressed in cultured neurons, all MTOR mutations identified here drive constitutive activation of mTOR complex 1 and enlarged neuronal size. CONCLUSIONS AND RELEVANCE: In this study, mutations of MTOR were associated with a spectrum of brain overgrowth phenotypes extending from FCD type 2a to diffuse megalencephaly, distinguished by different mutations and levels of mosaicism. These mutations may be sufficient to cause cellular hypertrophy in cultured neurons and may provide a demonstration of the pattern of mosaicism in brain and substantiate the link between mosaic mutations of MTOR and pigmentary mosaicism in skin.
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